555 research outputs found
Weakly- and Self-Supervised Learning for Content-Aware Deep Image Retargeting
This paper proposes a weakly- and self-supervised deep convolutional neural
network (WSSDCNN) for content-aware image retargeting. Our network takes a
source image and a target aspect ratio, and then directly outputs a retargeted
image. Retargeting is performed through a shift map, which is a pixel-wise
mapping from the source to the target grid. Our method implicitly learns an
attention map, which leads to a content-aware shift map for image retargeting.
As a result, discriminative parts in an image are preserved, while background
regions are adjusted seamlessly. In the training phase, pairs of an image and
its image-level annotation are used to compute content and structure losses. We
demonstrate the effectiveness of our proposed method for a retargeting
application with insightful analyses.Comment: 10 pages, 11 figures. To appear in ICCV 2017, Spotlight Presentatio
A Dilated Inception Network for Visual Saliency Prediction
Recently, with the advent of deep convolutional neural networks (DCNN), the
improvements in visual saliency prediction research are impressive. One
possible direction to approach the next improvement is to fully characterize
the multi-scale saliency-influential factors with a computationally-friendly
module in DCNN architectures. In this work, we proposed an end-to-end dilated
inception network (DINet) for visual saliency prediction. It captures
multi-scale contextual features effectively with very limited extra parameters.
Instead of utilizing parallel standard convolutions with different kernel sizes
as the existing inception module, our proposed dilated inception module (DIM)
uses parallel dilated convolutions with different dilation rates which can
significantly reduce the computation load while enriching the diversity of
receptive fields in feature maps. Moreover, the performance of our saliency
model is further improved by using a set of linear normalization-based
probability distribution distance metrics as loss functions. As such, we can
formulate saliency prediction as a probability distribution prediction task for
global saliency inference instead of a typical pixel-wise regression problem.
Experimental results on several challenging saliency benchmark datasets
demonstrate that our DINet with proposed loss functions can achieve
state-of-the-art performance with shorter inference time.Comment: Accepted by IEEE Transactions on Multimedia. The source codes are
available at https://github.com/ysyscool/DINe
Learning to Predict Image-based Rendering Artifacts with Respect to a Hidden Reference Image
Image metrics predict the perceived per-pixel difference between a reference
image and its degraded (e. g., re-rendered) version. In several important
applications, the reference image is not available and image metrics cannot be
applied. We devise a neural network architecture and training procedure that
allows predicting the MSE, SSIM or VGG16 image difference from the distorted
image alone while the reference is not observed. This is enabled by two
insights: The first is to inject sufficiently many un-distorted natural image
patches, which can be found in arbitrary amounts and are known to have no
perceivable difference to themselves. This avoids false positives. The second
is to balance the learning, where it is carefully made sure that all image
errors are equally likely, avoiding false negatives. Surprisingly, we observe,
that the resulting no-reference metric, subjectively, can even perform better
than the reference-based one, as it had to become robust against
mis-alignments. We evaluate the effectiveness of our approach in an image-based
rendering context, both quantitatively and qualitatively. Finally, we
demonstrate two applications which reduce light field capture time and provide
guidance for interactive depth adjustment.Comment: 13 pages, 11 figure
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